JP2003325508A - Ultrasonic diagnostic apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To locally monitor a temperature in an array transducer in an ultrasonic diagnostic apparatus. <P>SOLUTION: A plurality of representative oscillators are set in a plurality of oscillators 12, and a plurality of detection circuits 24 are provided corresponding thereto. Each detection circuit obtains information of power voltage, etc., from a transmission circuit connected to it, and detects transmission power. A temperature monitoring control circuit 26 compares information of the transmission power outputted from a plurality of the detection circuits 24 respectively with a judgment value, and carries out control for reducing the transmission power about an oscillator where rising of the temperature more than necessity is observed. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ultrasonic diagnostic apparatus, and more particularly to temperature control of array transducers (or ultrasonic probes).

[0002]

2. Description of the Related Art Generally, an ultrasonic probe (probe) has an array transducer including a plurality of vibrating elements. An ultrasonic beam is formed by the array transducer,
The ultrasonic beam is electronically scanned. Examples of the electronic scanning method include electronic linear scanning and electronic sector scanning.

In any case, a high-voltage transmission drive signal is supplied to each of the plurality of vibrating elements, so that ultrasonic waves are transmitted to each of the vibrating elements. The power loss in the electroacoustic conversion causes heat generation. That is, the array transducer generates heat, and the heat is conducted to each part of the ultrasonic probe. The heat conduction also heats the surface of the acoustic lens. Therefore, from the viewpoint of safety for living organisms,
It is very important to control the temperature of the array transducer or ultrasonic probe (there are laws and regulations, safety standards, etc.).

Some conventional ultrasonic diagnostic apparatuses perform temperature control by monitoring the voltage and current of a shared transmission power source, that is, by monitoring the total power for transmission. Further, the voltage of the transmission power supply is also reduced when the number of transmission pulses (wave number) increases.

However, in the prior art, since the entire array transducer was macroscopically evaluated and the power was uniformly controlled, more strict control could not be performed, and in some cases, excessive power could be limited. I may go. In the latter case, there is a problem that the sensitivity is lowered.

Here, on the premise of electronic linear scanning, the temperature distribution along the element array direction in the array transducer will be examined. For example, in the color flow mapping mode in which a two-dimensional color blood flow image (color Doppler image) is combined and displayed on a two-dimensional black-and-white tomographic image (B-mode image), one transmission for B-mode per beam address, Also, it is necessary to perform transmission 10 times for color Doppler (transmission conditions differ). In addition, the area where the color Doppler image is formed is often set to a part. In that case, the temperature at each position in the array transducer is not uniform, and the temperature in the range in which transmission for color Doppler is also performed rises. Therefore, if the temperature is uniformly evaluated, it will be mistaken locally.

On the other hand, there is also a method of obtaining the temperature by software calculation in consideration of the transmission condition, but the voltage of the transmission pulse, the wave number, the transmission interval, etc. are finely set in correspondence with various condition settings such as resolution priority and sensitivity priority. Since it is adjusted and the operation sequence is complicated, the amount of calculation is enormous and the content of the calculation is complicated.

An object of the present invention is to enable local temperature monitoring of array transducers.

Another object of the present invention is to enable local temperature control of the array transducer.

[0010]

In order to achieve the above object, the present invention provides an array transducer comprising a plurality of vibrating elements, and a transmitting section for outputting a transmission drive signal to the plurality of vibrating elements. A plurality of transmission power detection circuits provided corresponding to all or part of the plurality of vibrating elements, and a temperature monitoring control unit that performs temperature management based on detection results from the plurality of transmission power detection circuits, It is characterized in that the temperature of the array transducer can be locally controlled.

According to the above configuration, a plurality of transmission power detection circuits are provided for the array transducer, and it is possible to estimate the temperature or the temperature rise at each position of the array transducer by using them. That is, local temperature evaluation can be performed. The temperature can be individually monitored for all the vibration elements, or the temperature can be monitored for a representative vibration element among them. When electronic linear scanning or the like is adopted, it is desirable to set the interval between representative vibrating elements to be monitored in consideration of the size of the transmission aperture. With this configuration, it is possible to perform fine temperature control while suppressing an increase in circuit scale.

Preferably, a plurality of representative vibrating elements are discretely set with respect to the plurality of vibrating elements, and the transmitting section is supplied with a transmission power source and a voltage from the transmission power source.
A plurality of transmission circuits that excite a transmission pulse and output the transmission drive signal, and the transmission power detection is performed for each of a plurality of representative transmission circuits corresponding to the plurality of representative vibrating elements in the plurality of transmission circuits. A circuit is provided.

Preferably, each transmission power detection circuit detects the transmission power by referring to the power supply voltage of the transmission power supply or a voltage weighted to the power supply voltage and the transmission pulse. Since the transmission condition is reflected in the transmission pulse, if the transmission pulse itself is used as a reference in addition to the transmission voltage, the transmission power can be accurately obtained in consideration of the transmission condition at that time.

Preferably, the transmission power is detected at regular intervals. Desirably, the fixed period corresponds to one frame. Considering the average transmission power per unit time, both heat generation and heat dissipation can be considered.

Preferably, the temperature monitoring controller controls the transmission power of all of the plurality of vibrating elements when there is at least one excess detection result exceeding a determination value among the detection results of the plurality of transmission power detection circuits. Perform control to limit the.

[0016] Preferably, the temperature monitoring controller controls the excess detection result among the plurality of vibrating elements when there is an excess detection result exceeding a determination value among the detection results of the plurality of transmission power detection circuits. The control for limiting the transmission power is executed for some vibrating elements corresponding to. According to this configuration, fine temperature control can be performed.

Preferably, the limit of the transmission power is:
At least one of reducing the number of pulses, increasing the transmission repetition period, decreasing the voltage of the transmission drive signal, and reducing the number of transmissions per beam address is included.

Preferably, in a composite mode in which transmission / reception for the first mode and transmission / reception for the second mode are executed for each beam azimuth, the transmission power is limited only to the transmission / reception in the second mode. Desirably, the first mode is a mode for two-dimensional tomographic image formation, and the second mode is a mode for two-dimensional blood flow image formation.

In order to achieve the above object, the present invention provides an array transducer comprising a plurality of vibrating elements, a plurality of transmitting circuits for outputting a transmission drive signal to the plurality of vibrating elements, and a plurality of the plurality of transmitting circuits. Of the plurality of representative vibration elements among the plurality of vibration elements, the plurality of power detection circuits for detecting the power of the transmission drive signal output to each representative vibration element, and the detection results from the plurality of power detection circuits. On the basis of the above, a temperature monitoring control unit for performing temperature management for each local portion of the array transducer is included.

[0020]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a block diagram showing the configuration of the transmitting section of the ultrasonic diagnostic apparatus according to the present invention.

The array transducer 10 is provided in an ultrasonic probe (not shown). Array transducer 1
0 is composed of a plurality of vibrating elements 12, and the array transducer 10 forms an ultrasonic beam. The ultrasonic beam is electronically scanned, for example. The ultrasonic probe may be used by being brought into contact with the body surface, or may be inserted into the body cavity and used.

The transmission control circuit 14 controls the operation of the transmission circuit 18 provided for each vibrating element 12. Specifically, the transmission pulse is supplied to each transmission circuit 18 with a predetermined delay relationship. The operation of the transmission control circuit 14 is controlled by a host controller (not shown), and necessary signals such as a frame synchronization signal are input to the transmission control circuit 14. The transmission circuit group 16 is composed of a plurality of transmission circuits 18 in this embodiment. The transmission circuit 18 inputs a transmission pulse and outputs a transmission drive signal excited to the corresponding vibration element.

The signal received by each vibrating element 12 is input to the receiving section 20. Then, the reception unit 20 executes a phasing addition process or the like on the plurality of received signals.

In the present embodiment, the plurality of vibrating elements 1
In order to monitor the temperature of a plurality of representative vibrating elements as a representative of the two, the plurality of detecting circuits 24 are connected to the plurality of representative transmitting circuits corresponding to those representative vibrators. The detection circuit group 22 is configured by the detection circuits 24.

Each detection circuit 24 is a circuit that obtains predetermined information from the transmission circuit connected thereto and detects the transmission power (transmission power). Of course, other physical information may be detected as long as the temperature can be monitored.

The temperature monitoring control circuit 26 performs necessary operation control on the transmission control circuit 14 based on the detection results output from the plurality of detection circuits 24, that is, the information on the transmission power. Further, control information may be sent from the temperature monitoring control circuit 26 to the host controller.

In any case, the temperature monitoring control circuit 26
Compares the transmission power information output from each detection circuit 24 with a predetermined determination value, and determines the necessity of temperature limitation when the transmission power value exceeds the determination value.
Then, the temperature monitoring control circuit 26 instructs the transmission control circuit 14 to limit the transmission power to all the vibrating elements 12 or a part of the vibrating elements 12 when such a determination is made. Command to give.

In this case, only for the vibrating elements for which the temperature rise is estimated, specifically, for the vibrating element group in the periphery including the representative element for which the temperature rise is determined,
The transmission power may be limited locally.

The transmission power can be limited by various methods such as reduction of the number of transmission pulses, reduction of transmission voltage, and variable control for lengthening the transmission repetition period.

In FIG. 2, the array transducer 10 and the transmission aperture 1 are shown.
The relationship with 00 is shown. For example, if the smallest transmitting aperture is as shown in FIG. 2, then there are a plurality of discrete or regularly spaced so that there is at least one representative vibrating element within the smallest transmitting aperture. The representative vibrating element may be set. In FIG. 2, # 0,
The vibration elements # 8, # 16, ... Are selected as the representative vibration elements for temperature monitoring. Of course, in order to monitor the temperature more finely, detection circuits may be provided for the vibration elements of all channels.

FIG. 3 shows the principle of transmission power detection as a block diagram.

As described above, the transmission pulse is supplied to the transmission circuit 18, and the transmission pulse is specifically used as an input trigger of the switching circuit 34. The transmission power supply 3 is provided to the switching circuit 34 via the weighting circuit 32.
0 is connected, that is, the voltage from the transmission power supply 30 is applied to the switching circuit 34. Here, the weighting circuit 32 functions, for example, when weighting the voltage according to the position in the transmission aperture, and the transmission control circuit 14 shown in FIG. 1 adjusts the weighting amount. In the switching circuit 34,
When the transmission pulse is input, it is excited by using it as a trigger,
As a result, a high-voltage transmission drive signal is output to the corresponding vibrating element.

On the other hand, the voltage of the transmission power source 30 or the weighted voltage is applied to the detection circuit 24. Further, the transmission pulse is input to the detection circuit 24, and the detection circuit 24 obtains the transmission power from the voltage of the transmission power supply and the transmission pulse. In this case, a capacitor that charges the power from the transmission power supply 30 using the transmission pulse as a switching signal may be used, and the transmission power, that is, the transmission power may be obtained from the amount of charge accumulated in the capacitor per unit time. In this case, such capacitors are reset every predetermined period,
In that case, a frame synchronization signal can be used as the reset signal. That is, the average transmission power is obtained for each frame.

For example, in the color flow mapping mode in which the color Doppler image is combined with the B mode image, when the transmission power is limited, the transmission for the B mode is executed as it is, and the transmission for one of the color Doppler images is performed. The wave number, transmission voltage, etc. may be changed. Of course, the transmit power may be reduced for each of the two modes of transmission.

[0036]

As described above, according to the present invention,
Local temperature monitoring can be performed on the array transducer. Further, by controlling the temperature of the local array transducer locally, safety for the living body is achieved.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a transmission unit of an ultrasonic diagnostic apparatus according to the present invention.

FIG. 2 is a diagram showing a relationship between an array transducer and a transmission aperture.

FIG. 3 is a diagram for explaining detection of transmission power.

[Explanation of symbols]

10 array vibrator, 12 vibrating element, 14 transmission control circuit, 18 transmission circuit, 24 detection circuit, 26 temperature monitoring control circuit.

Claims (11)

[Claims] 1. An array transducer including a plurality of vibrating elements, a transmitter that outputs a transmission drive signal to the plurality of vibrating elements, and a plurality of vibrating elements provided corresponding to all or a part of the plurality of vibrating elements. A plurality of transmission power detection circuits, and a temperature monitoring control unit that performs temperature management based on detection results from the plurality of transmission power detection circuits, and performs local temperature management for the array transducer. An ultrasonic diagnostic apparatus characterized by being obtained. 2. The apparatus according to claim 1, wherein a plurality of representative vibrating elements are discretely set for the plurality of vibrating elements, and the transmitting unit supplies a transmitting power supply and a voltage from the transmitting power supply. A plurality of transmission circuits that excite the transmission pulse and output the transmission drive signal, and the transmission is performed for each of the plurality of representative transmission circuits corresponding to the plurality of representative vibrating elements in the plurality of transmission circuits. An ultrasonic diagnostic apparatus comprising a power detection circuit. 3. The apparatus according to claim 2, wherein each of the transmission power detection circuits refers to the power supply voltage of the transmission power supply or a voltage obtained by weighting the power supply voltage, and the transmission pulse. An ultrasonic diagnostic apparatus characterized by detecting transmission power. 4. The ultrasonic diagnostic apparatus according to claim 3, wherein the transmission power is detected at regular intervals. 5. The ultrasonic diagnostic apparatus according to claim 4, wherein the certain period corresponds to one frame. 6. The apparatus according to claim 1, wherein the temperature monitoring controller includes a plurality of detection results of the plurality of transmission power detection circuits when there is at least one excess detection result exceeding a determination value. An ultrasonic diagnostic apparatus characterized by executing control for limiting transmission power for all of the vibration elements. 7. The apparatus according to claim 1, wherein the temperature monitoring controller includes a plurality of vibrating elements when there is an excess detection result exceeding a determination value among the detection results of the plurality of transmission power detection circuits. Among them, the ultrasonic diagnostic apparatus is characterized by executing control for limiting transmission power for some of the vibration elements corresponding to the excess detection result. 8. The apparatus according to claim 6 or 7, wherein the transmission power is limited by reducing the number of pulses, increasing the transmission repetition period, decreasing the voltage of the transmission drive signal, and
An ultrasonic diagnostic apparatus comprising at least one of reduction in the number of transmissions per beam address. 9. The apparatus according to claim 6, wherein in the composite mode in which transmission / reception for the first mode and transmission / reception for the second mode are executed for each beam direction, the transmission / reception in the second mode is performed. The ultrasonic diagnostic apparatus is characterized in that the transmission power is limited only for the first time. 10. The apparatus according to claim 9, wherein the first mode is a mode for two-dimensional tomographic image formation and the second mode is a mode for two-dimensional blood flow image formation. Ultrasonic diagnostic equipment. 11. An array transducer including a plurality of vibrating elements, a plurality of transmitting circuits that output a transmission drive signal to the plurality of vibrating elements, and a plurality of representative vibrating elements among the plurality of vibrating elements. And a plurality of power detection circuits that detect power for the transmission drive signal output to each representative vibrating element, and based on the detection results from the plurality of power detection circuits, for each local portion of the array transducer. An ultrasonic diagnostic apparatus comprising: a temperature monitoring control unit that manages temperature.